An arrangement having a first converting element configured to convert an input current linearly into an auxiliary current, a second converting element configured to convert the auxiliary current into an output voltage, and a separating element configured to separate slow changes of the auxiliary current from fast changes of the auxiliary current, wherein the first, second, and separating elements are arranged as a dynamic control loop regulating the input current with the slow changes.
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16. A method for controlling an input current comprising:
converting an input current into a first auxiliary current;
converting the auxiliary current into an output voltage; and
dynamically regulating the input current according to a slow changing component of the first auxiliary current,
wherein the output voltage is dependent on a rapidly changing component of the auxiliary current.
28. An arrangement comprising:
a first converting means for converting an input current linearly into an auxiliary current;
a second converting means for converting the auxiliary current into an output voltage; and
a separating means for separating slow changes of the auxiliary current from fast changes of the auxiliary current,
wherein the first, second, and separating means are arranged as a dynamic control loop regulating the input current with the slow changes, and
wherein the output voltage is dependent on the fast changes of the auxiliary current.
1. An arrangement comprising:
a first converting element configured to convert an input current linearly into an auxiliary current;
a second converting element configured to convert the auxiliary current into an output voltage; and
a separating element configured to separate slow changes of the auxiliary current from fast changes of the auxiliary current,
wherein the first, second, and separating elements are arranged as a dynamic control loop regulating the input current with the slow changes, and
wherein the output voltage is dependent on the fast changes of the auxiliary current.
24. An input current controller arrangement comprising:
a converting element configured to convert an input current to a first auxiliary current, wherein the input current includes a slowly changing component and a rapidly changing component, and the slowly changing current component has a wide dynamic range of values requiring compensation;
a current to voltage converting element configured to generate an output voltage from the first auxiliary current, wherein the output voltage has a voltage level that constantly remains within defined limits; and
a dynamic control loop, which comprises:
an element configured to convert the first auxiliary current into a component that changes slowly and a component that changes rapidly; and
a current control element configured to regulate the slowly changing component of the first auxiliary current,
wherein the output voltage is dependent on the component that changes rapidly.
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This application claims priority to German Patent Application Serial No. 102007006347.6, which was filed Feb. 8, 2007, and is incorporated herein by reference in its entirety.
A large number of methods are known nowadays for data transmission in digital radio communication systems, RFID systems being one example. In accordance with the particular system, the data transfer takes place between a transponder, implemented, for example as a radio tag, and a reading device. At low communication frequencies, inductive fields provide the transmission medium, while electromagnetic fields are used at higher frequencies. In systems of this type the inductive or electromagnetic field is modulated by information. Modulation consists in a modification of the signal parameters of a carrier frequency, that are the amplitude, the frequency or the phase, in accordance with a modulating signal, known as the baseband signal.
The field has to be demodulated in order to regain the baseband signal, i.e. the real information. Since both the transponder and the reading device contain a source of information, and therefore an exchange of information in both directions takes place, both pieces of equipment often contain both a modulator and a demodulator.
To regain the information, an antenna is now used to extract electrical power from the field. An inductive current arises in the antenna coil as soon as it comes into the region of an electromagnetic field. The modulation of the field is thus converted into the modulation of a proportional electrical current. The information can now be detected in the changes of this current over time. Parallel circuits, also known as shunt circuits, are used to detect the current.
A digital radio communication system involves, amongst other things, a highly dynamic electromagnetic field. In other words, depending on the distance between the transmitting and receiving equipments, the information is transmitted in a form of a highly variable field. The modulated field therefore has a rapidly changing modulation component, representing the information, and a slower component resulting from changes in the distance between the transmitter and receiver, or from changes in the transmission medium.
After converting the field into a proportional current, it is therefore necessary to normalize the current before being able to process the information contained in the current any further, so that subsequent circuit elements are not loaded beyond appropriate limits.
Normalization of this type is referred to as dynamic compression. In the past, one way of achieving dynamic compression has been to use a number of diodes in series. Another way of achieving compression has been to use a specialized analogue/digital converter, in which two demodulation units are provided with variable sensitivity modules, thereby switching between several outputs.
Examples of the invention are explained below with reference to the drawings; the illustrations have been drawn so that components that are the same, or that have the same effect, are given the same reference. The elements illustrated are not to scale. For the sake of understanding, some elements have been shown disproportionately large or in an extremely simplified form.
A conversion unit 1, which converts an information modulated electromagnetic field into an electrical current, comprises a receiving unit 1a and a shunt circuit 1b. This shunt circuit might, for instance, be implemented as a parallel circuit. The transmitted information, which is present as a field at the receiving unit 1a, can be converted into rapid changes in electrical current by means, for instance, of a shunt resistor.
As a result of changes in the distance between the transmitter and receiver in this radio communication system, the electromagnetic field that carries the modulated field strength has a further modification superimposed upon it; it is, in other words, also modulated by the changing distance. One of the effects of larger changes in distance is that the field has a wide dynamic range, and this is reflected in a slow change in the current flowing through the shunt element. The changing current, comprising both a slow and a fast component, is now passed to a decoupling unit 2. The modulated current, which will be referred to below as the input current I1, is converted in a linear current converter 2a into an auxiliary current I1′, and is fed to a current/voltage converter 2b. An output voltage U1 is present at the output of the decoupling unit 2, which contains a dynamic control loop, and this voltage is passed to a demodulation unit 3. The information is extracted in the demodulation unit 3; the extraction will not be considered here in any more detail.
In
The input current I1, consisting of a rapidly changing current together with a slowly changing current, is now present at the input to the linear current converter 2a. This current converter 2a transfers all the current components of the input current I1 linearly, yielding the auxiliary current I1′ at its output. Due to the linear current conversion, both the slowly changing and the rapidly changing currents are present in the auxiliary current I1′. By means of the current/voltage converter 2b, an output signal U1, used for further processing of the information, is generated from the auxiliary current I1′. In addition to being passed to the current/voltage converter, the auxiliary current I1′ is also fed back. The regulating variable in this control loop is that proportion of the auxiliary current I1′ that contains the slowly changing current I5. The auxiliary current I1′ is filtered in a low-pass filter 2c in such a way that only that component of the current that is changing slowly I5 is present at the output of the low-pass module. The current I5 is converted in a current regulation circuit 2d to yield the second auxiliary current I3. This auxiliary current I3 is also referred to as the feedback variable. By means of the constant current I2 the additive superimposition of the input current I1 with the auxiliary current I3 results in compensation for the slow changes.
Dynamic regulation is implemented here through components 2c and 2d in the form of a feedback control loop. The variable regulated in this control loop is the current I5, which only contains the slowly changing component in the input current. If the feedback control loop 2c and 2d is now formed in such a way that currents I3 and I1 are additively superimposed, so that the slower changes in the current are compensated, then an output voltage U1 will be present at the output of the current/voltage converter 2b which will be at one level, modulated with the information.
As a result of this constant output level, subsequent circuits operate independently of the slow changes in current, and therefore independently of the changing distance between the transmitting and receiving units of such a communication system.
The input transistor N1 passes the input current I1. Because transistors P1 and P2 form a current mirror, they convert current I1 into an auxiliary current I1′. The output voltage U1 developed across resistor R1 and capacitor C1 is generated by the auxiliary current I1′. It follows that R1 is an element that converts current to voltage. The purpose of capacitor C1 here is merely to filter out those high-frequency components of the voltage spectrum that make no significant contribution to the information content. The auxiliary current I1′ is then converted into a second auxiliary current I3 with the aid of current regulator 3d. This is then additively combined with input current I1 in such a way that a constant current I2 is generated in the constant current source Q1.
In contrast to
In contrast to
These relationships are clarified through the current and voltage curves of
The difference as compared with
Because the variable current source Q2 is replaced by transistor P3, it is necessary for the difference voltage U6 in the feedback loop also to be able to adopt negative values. For this reason, the differential amplifier ΔU, in contrast to
The two possible implementations illustrated in
A circuit diagram of the example implementation is shown in
The difference from the foregoing figures consists primarily of some transistor references. The current mirror transistors are referred to in
The feedback loop also has a different structure. In
The output voltage level U1 is then set to a voltage through transistor N18. This static sensor output voltage charges or discharges the low-pass capacitor C3 through the current-controlled inverter consisting of transistors P24, P26 and N24. This inverter is biased by the N-channel or P-channel bias voltages U4 and U5. The voltage dropped across C3 controls the second auxiliary current I3, and this flows to the source terminal of input transistor N1. The constant current source, implemented in transistor N16, which is also biased by bias voltage U5, carries the additively superimposed constant current I2 in the drain-source channel, consisting of the input current I1 and the second auxiliary current I3.
The output voltage U1 is connected to the gate of transistor N25 for this reason. The drain of N25 is connected to the gate and source terminals of transistor P35. Its source, however, is connected to the source terminal of transistor N24 and the drain of N26. Similarly, the drain of N24 is connected to the source of P34. The gate of P34 has a connection to the gate of P35. The drains of P34 and P35 are connected to the positive power supply voltage. The gate terminal of N24 is joined to the gate and source terminals of P42 and to the drain of P43. The gate and source of P43 are at the reference potential GND. The drain of P42 is joined to the gate and source of P41. The drain of P41 is joined to the gate and source of P40. The drain of P40 is at the positive operating potential. The drain of N24 is connected to the drain of N27 and to the drain of P33. The gate of N27 is connected to the output of an inverter, while the gate of P33, on the other hand, is connected to the input of the inverter. The input to the inverter is labelled “HOLD”, and represents a voltage input. The sources of P33 and N27 are connected to the low-pass capacitor C3. From this point on, the feedback loop matches that shown in
The output voltage U1 is compared with the reference voltage U2 by a differential amplifier ΔU, consisting of N24 and N25. The output voltage U1 is therefore present at the input transistor N25 of the differential amplifier ΔU. The differential amplifier ΔU is loaded by a current mirror, consisting of P34 and P35, and is supplied with operating current through transistor N26, which is biased by voltage U5. The second input of the differential amplifier ΔU, which corresponds to the gate terminal of transistor N24, is fed from the reference voltage U2. This voltage U2 is obtained from a reference voltage source consisting of a series connection of transistors P40, P41, P42 and P43, tapped at the source terminal of transistor P42. This series circuit therefore comprises a potential divider, configured in such a way that the reference voltage level U2 is approximately 400 mV. The resulting output voltage from the differential amplifier U6 is now available at the drain terminal of transistor N24. This terminal is connected to the CMOS switch illustrated, consisting of P33 and N27. The CMOS switch thereby implements the sample-and-hold switch A. The switch A is driven by the inverter. When the “Hold” input is held high, the switch consisting of P33 and N27 is conductive, passing the difference voltage signal U6 to capacitor C3.
On the basis of the fact that the electrical current converted, referred to below as the input current, consists of a rapidly changing component and a slowly changing component, this invention provides equipment and a method for reducing the dynamic range. Because the information is only contained in the rapidly changing current component, the slow changes in current are compensated by means of a dynamic control loop. The control loop is designed in such a way that the working point of this control loop does not change in response to fast changes in the current. This results in data transmission that is independent of slow changes in current; in other words, it does not depend on the field strength and therefore not on the distance between the transmitting and receiving units, and provides the data with a constant level of output current.
Missoni, Albert, Klapf, Christian
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